000135908 001__ 135908
000135908 005__ 20240627150548.0
000135908 0247_ $$2doi$$a10.1016/j.tsep.2024.102686
000135908 0248_ $$2sideral$$a138919
000135908 037__ $$aART-2024-138919
000135908 041__ $$aeng
000135908 100__ $$0(orcid)0000-0002-4411-9834$$aLozano, Miguel A.
000135908 245__ $$aOptimal modes of operation and product cost allocation in sugarcane steam cogeneration plants
000135908 260__ $$c2024
000135908 5060_ $$aAccess copy available to the general public$$fUnrestricted
000135908 5203_ $$aSugar and ethanol production from sugar cane is one of the most competitive sectors of Brazil’s economy. The bagasse generated during the production process is used as fuel in cogeneration plants that provide thermal and electrical energy to the process. In the last decades, many sugar cane factories have produced a surplus of electricity that may be sold to the grid as a new product. This paper applies energy billing optimization and thermoeconomic analysis to a sugarcane steam cogeneration plant to determine the optimal operating mode of the plant, unveils the cost formation process of its internal products (refinery heat, process heat, and consumed electricity), and examines how the results are affected by: (i) the demand for the plant’s energy services, (ii) the availability of bagasse, and (iii) the selling price of surplus electricity. The thermoeconomic analysis involves a detailed study of the cost formation process, which is achieved through the decomposition of the steam cycle of the cogeneration plant into subcycles. Three main subcycles, in addition to the deaeration cycle and other auxiliary subcycles, have been identified: the cogeneration cycle generating work in the high-pressure turbine and refinery heat (subcycle one), the cogeneration cycle generating work in the high- and medium-pressure turbines and process heat (subcycle two), and the condensing cycle that generates only work in the high-, medium-, and low-pressure turbines (subcycle three). These subcycles make up the productive structure of the steam cogeneration plant and explain how water/steam goes through energy conversion processes from the bagasse energy to the heat and electricity produced. Both the optimization model and the thermoeconomic analysis serve as valuable tools for planning in response to potential changes in bagasse and electricity market prices, as well as fluctuating product demand conditions. In the base case, combining optimization with thermo-economic analysis, the unit monetary cost of the final products has been determined: heat for refinery (8.85 R$/MWh), electricity sold (183.60 R$/MWh), internally consumed electricity (41.51 R$/MWh), and process heat (8.85 R$/MWh).
000135908 536__ $$9info:eu-repo/grantAgreement/ES/DGA/T55-23R
000135908 540__ $$9info:eu-repo/semantics/openAccess$$aby-nc-nd$$uhttp://creativecommons.org/licenses/by-nc-nd/3.0/es/
000135908 655_4 $$ainfo:eu-repo/semantics/article$$vinfo:eu-repo/semantics/publishedVersion
000135908 700__ $$aSantos, Rodrigo dos
000135908 700__ $$aSantos, José J.C.S.
000135908 700__ $$0(orcid)0000-0002-5161-7209$$aSerra, Luis M.$$uUniversidad de Zaragoza
000135908 7102_ $$15004$$2590$$aUniversidad de Zaragoza$$bDpto. Ingeniería Mecánica$$cÁrea Máquinas y Motores Térmi.
000135908 773__ $$g52 (2024), 102686$$tThermal Science and Engineering Progress$$x2451-9049
000135908 8564_ $$s3569775$$uhttps://zaguan.unizar.es/record/135908/files/texto_completo.pdf$$yVersión publicada
000135908 8564_ $$s1980736$$uhttps://zaguan.unizar.es/record/135908/files/texto_completo.jpg?subformat=icon$$xicon$$yVersión publicada
000135908 909CO $$ooai:zaguan.unizar.es:135908$$particulos$$pdriver
000135908 951__ $$a2024-06-27-13:20:27
000135908 980__ $$aARTICLE